FR2859370A1 - CYCLONE SEPARATION DEVICE AND VACUUM CLEANER CONTAINING SUCH A DEVICE - Google Patents

Abstract

This cyclone separation device comprises a first cyclone (111) serving to separate the sucked air and a plurality of second cyclones (113), which are installed on an outer periphery of the first cyclone so as to surround the latter. vacuum cleaners incorporating cyclone dust collecting devices.

Description

The present invention generally relates to a device for

  cyclone separation and an aspirator comprising such a device.

  In general, a cyclone separating device is a device for separating dust and dirt using centrifugal force by producing a rotational flow inside a cyclone vortex chamber. is widely used in a variety of fields. U.S. Patent Nos. 3,425,192 and 4,373,228 disclose embodiments adopting such a cyclone separation device for an aspirator.

  The patents cited above describe a cyclone dust collection device for separating dust from air using a plurality of cyclones. In this arrangement, large dust particles or dirt are separated by the first cyclone, and the air from which dust or dirt has been separated enters the second cyclone or auxiliary cyclone. As a result, small particles of dust or dirt are separated and the purified air is discharged to the outside. U.S. Patent No. 3,425,192 discloses that the auxiliary cyclone is disposed on the upper portion of the first cyclone so that large dust particles are separated by the first cyclone, which is a main cyclone, and that the partially purified air enters in the auxiliary cyclone so that small dust particles are then separated. U.S. Patent No. 4,373,228 discloses a plurality of cyclone units formed such that the auxiliary cyclones are installed within the first cyclone.

  However, certain problems arise in the conventional cyclone separation device. First of all, since the connecting structure between the first cyclone and the auxiliary cyclone is complicated and a correct delivery of a suction force produced by the main body of the vacuum cleaner is difficult to obtain. the suction force and the cleaning efficiency are altered. Secondly, since the first cyclone and the auxiliary cyclone are not compactly arranged, the cyclone separator necessarily requires a large volume to properly perform an appropriate dust collection function. Therefore, the vacuum cleaner with the previously described cyclone separation device has a large structure and is difficult to maintain and the cleaning task is inconvenient for a user. Thirdly, since a connecting path between the first cyclone and the auxiliary cyclone is complicated, the manufacturing process is complicated. That's why the number of parts and the production costs are increased.

  Therefore, there is a need in the industry so far untreated, to eliminate the inconvenience and inadequacy mentioned above.

  An object of the present invention is to solve at least the problems and / or the disadvantages indicated above and to obtain at least the advantages described below. It is therefore an object of the present invention to provide a cyclone separation device having a compact structure, which can improve dust collection efficiency in a plurality of conventional cyclone dust collection devices and prevent tampering with the suction force, and a vacuum cleaner comprising such a device.

  To achieve the previously described aspects of the present invention, there is provided a cyclone separation device for an aspirator, characterized in that it comprises a first cyclone for separating the aspirated air, and a plurality of second cyclones, the second cyclones being installed on the outer periphery of the first cyclone so as to surround the first cyclone.

  In a preferred embodiment of the present invention, the first cyclone comprises a first chamber for centrifugally separating air containing dust, a first inlet formed in the first chamber and into which air including dust, and a first outlet formed in the first chamber, from which the air is evacuated. The first chamber can be made with a cylindrical shape. The first cyclone further includes a grid member installed upstream of the first outlet in the vortex chamber to prevent dust and dirt separated from the sucked air from flowing back through the first outlet.

  The grate member may include a gate body having a plurality of channels, a gate opening formed on one side of the gate body for exhausting air, the dust or dirt of which has been removed, by communication with the first outlet, and a screen member formed on the other side of the grid body, to prevent dust or dirt from flowing back.

  Each of the second cyclones comprises a second chamber for further separating the air separated by the first cyclone under the action of the centrifugal force, a second inlet formed in the second chamber and into which the air discharged from the first cyclone penetrates, and a second outlet formed in the second chamber for exhausting air from which dust has been removed.

  The second chamber is arranged such that a predetermined portion on one end includes a conical shape. The cyclone separation device may further comprise an inlet-outlet hood installed on an upper portion of the first cyclone and the second cyclone to establish communication between the first outlet of the first cyclone and the second inlet of the second cyclone, and a cyclone hood installed on an upper part of the inlet-outlet hood. A cyclone hood can be installed on the top of the I / O hood. The input-output hood includes an air duct for connecting the first output to the second input and may include an output duct for establishing communication with the second output of the second cyclone.

  A predetermined portion of the outlet duct is inserted into the second outlet when the inlet-outlet hood is connected to the second cyclone so that air is discharged through the outlet duct. The output conduit is configured such that one end is connected to the second output of the second cyclone and the other end opens upwardly relative to said input-output hood. The inlet-outlet hood also comprises, in its center, an integral type of duct allowing the air evacuated from each of the outlet ducts, to form a discharge stream in the center. Similarly, the integral type duct may include an opening at its upper part. The cyclone hood has a conical shape, the upper and lower spaces are open, and the first cyclone and each of the second cyclones are integrally formed. A partition wall is installed between the second cyclones.

  The above-mentioned objects and advantages and other objects and advantages are attained by means of a vacuum cleaner, characterized in that it comprises a main body for producing a suction force by suction of the dust-laden air , a suction brush for sucking up dust from a base, which is a surface to be cleaned, using the suction force, and communicating with the main body of the vacuum cleaner, and a cyclone separating device installed in the main body of the vacuum cleaner. The cyclone separation device comprises a first cyclone and a plurality of second cyclones for separating the aspirated air, and the second cyclones are installed on an outer periphery of the first cyclone so as to surround the latter.

  In one embodiment of the present invention, the first cyclone comprises a first chamber for centrifugally separating dust-containing air, a first inlet formed in the first chamber and into which air including dust, and a first exit formed in the first chamber, from which the air is evacuated. Each of the second cyclones comprises a second chamber for further separating the air separated by the first cyclone under the action of the centrifugal force, a second inlet formed in the second chamber and into which the air discharged from the first cyclone penetrates, and a second outlet formed in the second chamber for exhausting air from which dust has been removed.

  Other systems, methods, features, and advantages of the present invention will become apparent to those skilled in the art upon reading the accompanying drawings and the following detailed description. The set of such systems, methods, features and additional benefits included in the present disclosure are within the scope of the present invention.

  Other features and advantages of the present invention will become apparent from the detailed description hereinafter made with reference to the accompanying drawings, in which the components are not necessarily represented in the scale, since we insist instead, on the clear illustration of the principles of the present invention, and on which like reference numerals designate parts which correspond to all the different views, and in which: - Figure 1 is a drawing showing an exploded perspective view of an essential portion in a cyclone separator according to one embodiment of the present invention; Fig. 2 is a drawing showing a cross-sectional view of a cyclone separator according to one embodiment of the present invention; Fig. 3 is a drawing showing a partially cross-sectional perspective view of a cyclone separator according to one embodiment of the present invention; Fig. 4 is a drawing of a perspective view showing a cyclone separator according to one embodiment of the present invention; Fig. 5 is a drawing showing a cross-sectional view of a sled type vacuum cleaner having a cyclone separating device according to an embodiment of the present invention; and Fig. 6 is a drawing showing a perspective view of a vertical type vacuum cleaner which utilizes a cyclone separator according to one embodiment of the present invention.

  Hereinafter certain embodiments of the present invention will be described with reference to the accompanying drawings.

  The cyclone separating device according to the present invention includes a first cyclone 111, a plurality of second cyclones 113, an inlet-outlet hood 190 installed on the top of the first cyclone 111 and second cyclones 113, a cyclone hood. 191 and a dust collection unit 165. A plurality of second cyclones 113 are installed on the outer periphery of the first cyclone 111 so as to envelop the first cyclone 111. The first cyclone 111 and each of the second cyclones 113 are formed of a only holding, and a partition wall 250 is installed between the second cyclones 113, as shown in Figure 3. The partition wall 250 separates the space between the second cyclones 113 so as to form the device 100 of cyclone separation. A chamber wall 147 is made with a cylindrical shape around the second cyclones 113. The wall 147 of the chamber can be made with a variety of polygonal shapes depending on the wall 147 of the chamber, structured in a body 10 of the chamber. vacuum cleaner (Figures 5 and 6).

  The first cyclone 111 comprises a first chamber 115, a first inlet 121, a first outlet 123 and a grid element 130. The first chamber 115 is made with a cylindrical shape and separates the dust-laden air by the use of a centrifugal force, producing a rotational flow. The grid member 130 is installed upstream of the first outlet 123. Through the use of the grid member 130, the dust separated from the sucked air does not flow back through the first outlet 123.

  The gate member 130 includes a gate body 131 having a plurality of conduits, a gate opening 133, and a screen member 135. The gate opening 133 is formed on one side of the gate body 131 in communication with the gate body. first outlet 123 so as to evacuate the air, the dust or dirt has been removed. The screen member 135 is formed on the other side of the grid body 131 to prevent the dust or separated dirt from flowing back.

  The second cyclone 113 includes a second chamber 145, a second inlet 141, and a second outlet 143. The second chamber 145 is constructed in such a way that a portion on one end has a conical shape and separates the charged air from dust, using centrifugal force. The air discharged from the first cyclone 111 enters the second inlet 141, and the air separated by the second chamber 135 is discharged into the second outlet 143.

  The inlet-outlet hood 190 is installed on the upper part of the first cyclone 111 and the second cyclones 113 and includes an air duct 197 for establishing a communication between the first outlet 123 of the first cyclone 111 and the second inlet 141 of the first cyclone 111. second cyclone 113, and an outlet duct 199. The outlet duct 199 communicates with the second outlet 143 of the second cyclone 113 and is inserted into the second outlet 143 of the second cyclone 113. When the inlet-outlet cover 190 is connected at the second cyclone 113, a predetermined portion of the outlet conduit 199 is inserted into the second outlet 143 so that purified air can be discharged through the outlet conduit 199. One end of the outlet conduit 199 is connected to the second output 143 of the second cyclone 113, and the other end is open in the upper direction of the inlet-outlet hood 190. The cyclone hood 191 is made with a conical shape, of which The air vented from the second outlet 143 of the second cyclone 113 accumulates, and the air is evacuated at the top of the inlet-outlet hood 190. If the air exhausted from the second outlet 143 of the second cyclone 113 accumulates, the air is evacuated. the outside of the cyclone separating device 100 via an upper opening 193 formed in the upper space of the cyclone hood 191.

  The dust collection unit 165 includes a first dust collecting pot 161 and a second dust collection pot 163, the first dust collecting pot 161 being integrally formed with the second pot 163 of the dust collecting unit. dust. The second dust collecting pot 163 is made with a cylindrical shape and is removably connected to the wall 147 of the chamber, formed on the outside of the second cyclone 113. The first dust collecting pot 161 is made under the form of a cylindrical tube, is installed inside the second dust collecting pot 163 and is removably connected to the first chamber 115 of the first cyclone 111.

  FIG. 4 represents another embodiment of a cyclone separation device according to the present invention, in which the only difference lies in the shape of the inlet / outlet hood, and without the need to use a cyclone hood. 191. With reference to FIG. 4, outlet ducts 199 of an inlet / outlet cover 190 extend respectively from the second outlets 143, in a manner corresponding each to each of the second outlets 143 of the second cyclone. 113. One end of each outlet duct 199 is connected to the second outlet 143 extending from this second outlet 143 and is connected to an integral type duct 212 located in the center of the inlet-outlet hood 190. An opening 214 is formed at an upper portion of the integral type conduit 212. Therefore, exhaust air forms a single stream discharged into the integral type conduit 212.

  As shown in FIG. 5, a dust collection chamber 12 is interrupted and separated by a partition wall 17 located on one side inside the main body 10, and a cyclone separating device 100 is arranged to Inside the dust collection chamber 12. On a top side of the periphery of the cyclone separating device 100, a first inlet 121 for drawing air and dust entrained in the cyclone separating device 100 by means of a flexible hose 15 of the vacuum cleaner when the suction force is produced by a motor (not shown) is formed. In addition, at the central portion of the upper end of the cyclone separating device 100, an upper opening 193 for discharging the rising air is formed, from which dust and dirt have been removed by force. centrifugal, among the air laden with dust and dirt, which is entrained in the cyclone separating device 100. The cyclone separating device 100 can be adapted to a vertical type vacuum cleaner as well as to a sled type vacuum cleaner and will be described below with reference to Figure 6 the vacuum cleaner, in which the cyclone separating device 100 is adapted.

  A vacuum generating device (not shown), a motor operating part, is disposed inside the main body 10. Similarly, a suction brush 60 is movably connected to the lower side of the main body 10, and a cyclone mounting portion 65 is formed on the central front portion of the main body 10. An air suction duct 70 for connection to the suction brush 60 and an air exhaust duct 75 for connected to the motor operating portion, are disposed within the cyclone mounting portion 65.

  The first inlet 121 of the cyclone separating device 100 communicates with the air suction duct 70, and the upper opening 193 communicates with the air exhaust duct 75 so that dust and dirt are separated. while the dust-laden air sucked by the suction brush 60 passes through the cyclone separating device 100 and purified air is discharged to the outside through the upper opening 193 and the exhaust duct. air 75.

  The operations of the cyclone separating device 100 having the arrangement indicated above and the vacuum cleaner comprising such a device will be described below with reference to FIGS. 1 to 6.

  If the suction force is produced in the main body 10, the suction brush 60 connected to the main body 10 of the aspirator draws dust-laden air from the ground, which is a surface to be cleaned, using the suction force. The air sucked in this way enters the first chamber 115 in a tangential direction along the first inlet 121 of the cyclone separator 100 and is separated by the first cyclone 111 by the use of centrifugal force, so that large dust particles are collected in the first dirt collection pot 161. More specifically, the first cyclone 111 separates large particles of dust or dirt by absorbing dust-laden air using the suction force produced by the main body 10 of the vacuum cleaner. The first chamber 115 of the first cyclone 111 produces a centrifugal force under the effect of the rotating air entering through the first inlet 121, along the inner wall of the first chamber 115 in a direction tangential to the first chamber . Therefore, since the air having a relatively low weight is subjected to a low centrifugal force, this air collects in the central part of the first chamber 115, produces a swirling wind and is evacuated while circulating (evacuation flow). towards the first exit 123. On the contrary, since the dirt, relatively heavier than the air, is subjected to an intense centrifugal force, the dirt flows along the inner wall of the first chamber 115 and is collected at the first pot 161 of dust collection.

  On the other hand, the air, from which the large dust particles or dirt have been separated, passes through the first outlet 123 of the first chamber 115, circulates in the first air duct 197 and finally enters the second chamber 145 in a second chamber. tangential direction passing through the second inlet 141 of the second cyclone 113. Since the air duct 197 extends in radial form from the center, an intense stream of air, of which dust and dirt have been removed, turns into a weak airflow. Therefore the process of separating the air in the second cyclone 113 is easily realized. The air, which has entered the second chamber 145, is further separated by centrifugal force so that small dust particles or dirt are collected in the second dirt collecting pot 163. Fine dust particles are collected in the second dust collecting pot 163 by means of a plurality of second cyclones 113.

  The partition wall 250 formed between the second cyclones 113 prevents the dust from backflowing to a certain degree and makes it less difficult to collect dust as the separated dust falls into the second dirt collecting pot 163.

  Air, further separated by centrifugal force, passes through the second outlet 143 of the second cyclone 113, flows into the second outlet conduit 199 of the inlet-outlet hood 190, and collects at the cyclone hood 191. and finally is discharged through the upper opening 193 formed in the upper part of the cyclone body 191 (see FIG. 2). Referring to FIG. 4, the air enters through the outlet duct 199 of the inlet-outlet hood 190, passes through the integral duct 212, collects in a single air flow and is finally exhausted by the opening 214 of the integral type conduit 212. Therefore, the second cyclone 113 again separates fine particles of dust or dirt, air which has been separated mainly by the first cyclone 111. Specifically, the device of FIG. cyclone separation 100 improves the dust collection efficiency by executing the main separation operation at the first cyclone 111, and executing the secondary separation operation at a plurality of second cyclones 113.

  In the cyclone separation device 100, the distance between the first output 123 of the first cyclone 111 and the second input 141 of the second cyclone 113 is reduced compared to the patents cited in the description of the associated technique, so that an alteration the suction force is prevented and the dust collection efficiency is improved. The air evacuated from the cyclone separating device 100 by means of such a process is discharged to the outside through the main body 10 of the vacuum cleaner.

  As is evident from the foregoing, although in the conventional cyclone separator there is a problem related to a low dust collection efficiency, and to a certain degree at a limit by preventing an alteration of the suction force, in accordance with the present invention the second cyclones are disposed along the outer periphery of the first cyclone and the structure is compact. Therefore, an alteration of the suction force does not occur, and the dust collection efficiency is improved. Therefore, since the structure is compact and occupies a smaller space without any alteration of the dust collection efficiency, it is possible to realize a cyclone separation device and a vacuum cleaner comprising this device, which are satisfactory from the point of view of view of the user's preference, which further increases the competitiveness of the product.

  Although the invention has been shown and described with reference to certain preferred embodiments, one skilled in the art will appreciate that various changes in shape and detail can be made without departing from the scope of the invention. 'invention. Therefore, all the correct modifications, changes, and equivalents of the embodiments of the present invention are within the scope of the invention.

Claims (19)

  1. A cyclone separation device for a vacuum cleaner, characterized in that it comprises: a first cyclone (111) for separating the aspirated air, and a plurality of second cyclones (113), the second cyclones (113) being installed on the outer periphery of the first cyclone (111) so as to surround the first cyclone.   2. Device according to claim 1, characterized in that the first cyclone (111) comprises a first chamber (115) for centrifugally separating the air containing dust, a first inlet (121) formed in the first chamber ( 115) and into which the air including the dust penetrates, and a first outlet (123) formed in the first chamber (115), from which the air is exhausted.   3. Device according to claim 2, character-20 in that the first chamber (115) has a cylindrical shape.   4. Device according to claim 2, characterized in that the first cyclone (111) further comprises a grid-shaped element (130) installed upstream of the first outlet (123) in the vortex chamber to prevent dust and the dirt separated from the sucked air does not flow back through the first outlet.   Device according to claim 4, characterized in that the grid element (130) comprises: a grid body (131) having a plurality of channels, a grid opening (133) formed on one side of the grid body for exhausting air, from which dust or dirt has been removed, by communication with the first outlet (123), and a screen member (135) formed on the other side of the grid body (131), for prevent dust or dirt from flowing back.   6. Device according to claim 2, characterized in that each of the second cyclones (113) comprises: a second chamber (145) for further separating the air separated by the first cyclone (111) under the action of the centrifugal force, a second inlet (141) formed in the second chamber and into which the exhaust air of the first cyclone (111), and a second outlet (143) formed in the second chamber, for exhausting the air, the dust has been removed.   7. Device according to claim 6, characterized in that the second chamber (145) is formed with a predetermined portion on a cone-shaped end.   8. Device according to claim 6, characterized in that the cyclone separating device further comprises: an inlet cap (190) installed on an upper part of the first cyclone (111) and the second cyclone (113). ) to establish a communication between the first output of the first cyclone and the second input of the second cyclone, and a cyclone hood (191) installed on an upper part of the input-output hood (190).   Apparatus according to claim 8, characterized in that the inlet-outlet hood (190) has an air duct (197) for connecting the first outlet (123) to the second inlet (141), and an outlet duct (199) for communicating with the second outlet (143) of the second cyclone (113).   Apparatus according to claim 9, characterized in that a predetermined portion of the outlet duct (199) is inserted into the second outlet (143) when the inlet-outlet hood (190) is connected to the second cyclone. (113) so that the air is discharged through the outlet duct (199).   11. Device according to claim 10, characterized in that the outlet duct (199) is configured such that one end is connected to the second outlet (143) of the second cyclone (113) and the other end mity opens upwardly relative to said input-output hood (190).   12. Device according to claim 11, characterized in that the inlet-outlet cover (190) further comprises an integral type duct (212) allowing the exhaust air from each of the outlet ducts (199), form an evacuation stream in the center.   13. Device according to claim 12, characterized in that the integral type duct (212) has an opening (214) in an upper part.   14. Device according to claim 8, characterized in that the cyclone hood (191) has a conical shape, the upper and lower spaces are open.   15. The device of claim 1, wherein the first cyclone (111) and each of the second cyclones (113) are integrally formed.   16. Device according to claim 1, characterized in that partition walls (250) are installed between the second cyclones (112).   17. Vacuum cleaner, characterized in that it comprises a main body (10) for producing a suction force by suction of the dust-laden air, a suction brush (60) for sucking the dust from a base, which is a surface to be cleaned, using the suction force, and communicating with the main body (10) of the vacuum cleaner, and a cyclone separating device (100) installed in the main body (10). ) of the vacuum cleaner, and in that the cyclone separating device (100) comprises a first cyclone (111) and a plurality of second cyclones (112) for separating the sucked air, and the second cyclones (113) are installed on an outer periphery of the first cyclone to surround it.   Vacuum cleaner according to claim 17, characterized in that the first cyclone (111) comprises a first chamber (115) for centrifugally separating the air containing dust, a first inlet (121) formed in the first chamber ( 115) and into which the air including the dust penetrates, and a first outlet (123) formed in the first chamber (115), from which the air is exhausted.   Vacuum cleaner according to claim 17, characterized in that each of the second cyclones (113) comprises: a second chamber (145) for further separating the air separated by the first cyclone (111) under the action centrifugal force, a second inlet (141) formed in the second chamber and into which the air discharged from the first cyclone (111), and a second outlet (143) formed in the second chamber, for discharging air from the dust has been removed.